US2503407A - Method of making laminated fiberboard - Google Patents

Description

Patented Apr. 11,, 1950 METHOD OF MAKING LAMINATED FIBERBOARD Henry J. Perry, Beaver Falls, N. Y., asslgnor to The J. P. Lewis 00., Beaver Falls, N. Y., a corporation of New York No Drawing. Application April 19, 1945,

, Serial No. 589.274

6 Claims. (Cl. 154-132) This invention relates to laminated fiber board, and relates more particularly to the manufacture of resin impregnated laminated fiber board.

The objects of the present invention are to provide an improved resin impregnated laminated fiber board of desirable characteristics useful for a wide range of industrial purposes, and a, convenient and inexpensive method of making the same.

Laminated fiber board has heretofore been proposed in which the separate laminations are made from a beater furnish of kraft pulp and extracted pine wood pitch, sheeted on a wet machine or a cylinder machine, with the dried sheets compacted under heat and pressure to form a hard, stiff laminated fiber board. This known'product, although useful, is subject to a number of disadvantages, such as warping and mottling (both probablydue to the comparatively low water resistance of the product), low abrasion resistance, and, frequently, separation of the plies. The product of the present invention constitutes an improvement upon laminated fiber board of this general character, and possesses markedly better physical properties in the respects just mentioned, as well as in other characteristics.

According to the present invention, a beater furnish is prepared containin preferably steamed ground wood, kraft or other long fiber pulp, extracted pine wood pitch, rosin, size and alum. If desired, a plasticizer for the pine wood pitch may alSO be employed. A preferred composition includes 45 percent of steamed ground wood, percent of kraft pulp, and 40 percent of extracted pine wood pitch, all being dry weight percentages. The total wood fiber content (steamed ground wood and kraft pulp) may vary from about 50 to 75 percent of the mixture, and the pine wood pitch may vary correspondingly from about 50 to 25 percent. To this is added rosin size in the amount of l to 3 percent dry weight based on the total wood fiber content and a plasticizer in the amount of 10 to percent dry weight based on the content of the resin (extracted pine wood pitch). The alum is a final addition to the beater and is preferably added in such amount as to give a hydrogen ion concentration in the range pH 4.0 to 5.0.

The steamed ground wood is prepared in the conventional manner by steaming blocks of wood usually about two feet long for eight hours with saturated steam at fifty pounds gauge pressure. The softened blocks are then ground into pulp using a grinding wheel and water. The pulp is screened and made into laps in the usual manher. The product is a partially hydrolyzed, high lignin pulp containing various wood acids. I prefer to use hardwood blocks, such as birch, beech and maple, because of the cost factor and also because I believe that hardwood results in a better product, but softwood may be employed. In either case, the wood should preferably be one having a high lignin content.

The kraft pulp employed is wholly conventional. Any other long fiber pulp, such as sulphite pulp. may be used, but kraft pulp is preferred because of its cheapness. Although I prefer to employ a minor proportion of kraft or other lon fiber wood pulp as compared to the ground wood, the long fiber pulp may be entirely omitted and replaced by the cheaper ground wood, although at some satrifice in tensile strength of the finished produc The extracted pine wood pitch which I have used is that commercially available under the trade-mark Vinsol." It is a by-product of the production of wood rosin from pine Wood. The pine wood is usually first steamed to remove vola' tile oils, such as turpentine and pine oil, and then extracted with a solvent such as gasoline. The extract is distilled to remove the solvent and the volatile oils if the latter were not first recovered by steaming. The residue after distillation is treated to remove refined rosin. The remaining residue is the extracted pine wood pitch which is an essential ingredient. of the laminated fiber board of the present invention. This pitch comprises oxidized resin acid, oxidiz'ed abletic acid, oxidized terpenes, polyphenols, polymerized terpenes and usually ligneous matter. The physical properties of this pine wood pitch are well known, and for present purposes, it will suflice to add that it is a thermoplastic natural resin. Vinsol may be obtained commercially in a finely pulverized form, and this I prefer to use.

A suitable plasticizer for the pine wood pitch is methyl abietate, which is commercially available under the trade-mark Abalyn. .The Abalyn is emulsified in water by the aid of a suitable emulsifying agent such as potassium oleate,

usually formed during the emulsifying process by reaction between oleic ac d and potassium hydroxide. The emulsifying step is well known and need not be further described. I prefer to use 15 percent dry weight of Abalyn based on the dry weight of Vinsol. Other suitable plasticizers are methyl dihydroabietate and tricresyl phosphate, which may be similarly used.

The rosin size which it is preferred to use in the beater furnish is the conventional rosin size of the paper industry. The rosin size not only assists in retention of the pine wood pitch by the fibers, but has the further advantage of enhancing the water resistance of the product. This latter function is due to the precipitation of the rosin size by the alum in the form of insoluble aluminum soaps. Despite these advantages, the rosin size is not entirely essential, and may be omitted if desired.

The beater furnish prepared as above described, except for the alum, is mixed in the beater for a period sufficiently long for thorough mixing, say about one hour, thus forming a homogeneous mixture. provides a favorable pH value and precipitates the rosin size as above described. It also serves to break the emulsion of the plasticizer (if used) and thus precipitate the plasticizer.

The mixture discharged from the beater passes in the usual manner through a refiner or grinding The alum is then added. The alum mill, over a screen, into a mixing box where it is diluted with water, and thence to a conventional paper machine where it is formed into a continuous web. I prefer to use a cylinder machine, but other well known types of paper machines may be used. The web obtained from the cylinders is squeezed between woolen blankets to remove water, and is then partially dried by passing between steam heated cast iron cylinders. After this treatment, the partially dried web contains in the neighborhood of six to seven percent of water.

According to my invention, the partially dried web obtained as above described is then coated with thermosetting synthetic resin. For this purpose I prefer to wet the web with a water solution of partially condensed, water soluble phenolaldehyde resin, preferably in the proportion of 70 percent of resin to 30 percent of water. Such resins are available in the market in the form of water solutions. Suitable resins are PR-507 made by Resinous Products and Chemical Corporation and Resinox 468 made by Monsanto Chemical Company. It will be evident to those skilled in this art that any other thermosetting synthetic resin compatible with Vinsol might be employed.

I may perform the coating operation by passing the web through a bath of the resin solution, in which case both surfaces of the web are coated, or by passing the web between a pair of rollers the lower of which is partially immersed in the bath, in which case one side of the web is coated. The resin does not permeate the web, but lies largely on the surface, extending into the web only a few thousandths of an inch. This is due in considerable part to the water resistance imparted to the web by the precipitated rosin size. Because of the surface character of this resin treatment, the resin water solution does not disintegrate or weaken the web. This treatment coats one side of the web with from 5 to 7 percent and both sides with from-10 to 14 percent of the synthetic resin, by weight based on the dry weight of the web. Since the only purpose of this treatment is to form a surface coating of the synthetic resin on the web, any other suitable method, such as spraying a synthetic resin solution on the web, could be utilized.

After being moistened with the thermosetting synthetic resin water solution, the web is passed through squeeze rolls, and then over drier cylinders such as already described. The dried web is then calendered, using cold cast iron rolls. At

this stage, the water content of the calendered, The web resin-coated web is 5 percent or less.

may then be sheeted by a conventional sheeter or wound up into rolls of convenient length.

The resin-coated sheets are now ready for curing or molding under heat and pressure to the desired form, which may be sheet. rod, tube or some less conventional shape. All such shapes are intended to be included under the term fiber board as used herein. The sheets are superimposed one on another, until a laminate is built up of a thickness which, after compression, will give a finished product of, the desired thickness. Where a product of substantially equal strength in both directions is desired, the alternate sheets should be crossed with respect to the direction of their fiber structure. This, however, introduces some difliculty with respect to warping, because the fibers shrink more in diameter than in length. For general uses, therefore, I prefer to arrange all of the superimposed sheets with their fiber structure extending in the same general direction. A sheet coated on both sides should be used for at least one of the outside sheets of the laminate, but sheets coated on only one side may be used for the other sheets, it being understood that the sheets are arranged so that there is at least one resin coating between each pair of sheets and also a resin coating on each outer surface of the laminate.

The laminate is then molded in the usual manner at a pressure of from to 1000 pounds per square inch and at a temperature of from 250 F. to 350 F. I prefer a pressure of about 750 pounds per square inch and a temperature of about 300 F. It will be evident to those skilled in this art that this curing step results in fusing the resins and causing them to flow into intimate contact with each other and with the pulp, as well as completing the condensation of the phenolic resin and causing it to set.

The improved product made according to this invention has practically no tendency to separate at the plies, has a low water absorption in the neighborhood of 1 to 3'percent (usually nearer the lower level), is relatively free from mottling and warping during or after curing, and has high abrasion and mar resistance. My improved product is also harder than the prior art commercial product made from Vinsol and kraft pulp, has more resistance to deformation, has less tendency to crack or check on flexing, and has higher tensile strength and fiexural strength. My product is higher than the Vinsol-kraft product in short-time dielectric strength and substantially equal in step-by-step dielectric strength, but is somewhat lower in arc resistance.

My product is definitely better in heat distortion and flammability, distorting at a higher temperature and burning more slowly than the Vinsol-kraft product. The latter, however, has the advantage in impact strength. Certain chemical reagents attack both products seriously, but my product is resistant to some reagents which disintegrate the Vinsol-kraft product. Tests with eight common chemical reagents to which both products are reasonably resistant showed in all cases an increased resistance for my product. All the foregoing physical properties were determined using standard test procedures.

I attribute the improved characteristics of my product particularly to the use of the steamed ground wood and to the surface coating of the plies with thermosetting synthetic resin. As pointed out above, the ground wood should have a high content of lignin. I believe that this 'lignin is activated during the partial hydrolyzing of the steaming step and serves as a connecting medium between the fiber and the Vinsol and between the Vinsol and the synthetic resin, resulting in a strongly united composition of high strength and high resistance to attacking forces and reagents. It would be expected that the substitution of a long fiber pulp such as kraft pulp for the short fiber ground wood would give a better product, but I have found the contrary to be the fact. The use of the rosin size is advantageous but not essential. A plasticizer is desirable in some instances and undesirable in others, depending upon the use to which the product is to be put, and, in any event, the plasticizer merely performs its expected functions.

Although I have thus described my product and process in considerable detail and in the best form of which I am aware, in accordance with the patent statutes, it will be evident to those skilled in this art that changes may be made therein without departing from the spirit of my invention. I desire to be limited, therefore, only by the prior art and the scope of the appended claims.

I claim:

1. The method of making a hard, stifl, laminated fiber board, which comprises subjecting blocks of wood to the action of steam and then grinding the steamed blocks, thereby producing a partially hydrolyzed ground wood containing lignin and wood acids, preparing a beater furnish containing said steamed ground wood and extracted pine wood pitch, beating said furnish into a homogeneous mixture, forming said mixture into a web, partially drying the web, coating at least one side of said partially-dried web with thermosetting synthetic resin, superimposing sheets of said coated web to form a laminate having at least one resin coating between each pair of sheets and a resin coating on each outer surface of the laminate, and consolidating said laminate, causing said resins to flow, and setting said thermosetting resin, by subjecting the laminate to heat and pressure.

2. The method according to claim 1 in which said resin coating step is performed by wetting the partially dried web with a water solution pulp in minor proportion as compared to the quantity of said steamed ground wood, and in which said resin coating step is performed by wetting the partially dried web with a water solution of partially condensed phenol-aldehyde resin and partially drying said wetted web.

5. The method of making a hard, stifi, laminated fiber board, which comprises subjecting blocks of wood to the action of steam and then mixture, forming said mixture into a web, partially drying the web, coating at least one side of said partially dried web with thermosetting synthetic resin, superimposing sheets of said coated web to form a laminate having at least one resin coating between each pair of sheets and a resin coating on each outer surface of the laminate, and consolidating said laminate, causing said resins to flow, and setting said thermosetting resin, by subjecting the laminate to heat and pressure.

6. The method according to claim 5 in which said resin coating step is performed by wetting the partially dried web with/a water solution of partially condensed phenol-aldehyde resin and partially drying said wetted web, and in which the resin coating on one side. of said web constitutes approximately 5 to 7 percent by weight based on the dry weight of the uncoated web.

HENRY J. PERRY.

REFERENCES CITED The following references are of record in tho file of this patent:

UNITED STATES PATENTS Number Name Date 1,398,143 Novotny Nov. 22, 1921 2,080,078 Mason et al May 11, 1937 2,115,496 Maters Apr. 26, 1938 2,120,137 Mason June 7, 1938 2,196,277 Schorger Apr. 9, 1940 2,264,189 Richter Nov. 25, 1941 2,376,687 Goldstein May 22, 1945 2,459,851 Story Jan. 25, 1949

Claims (1)

1. THE METHOD OF MAKING A HARD, STIFF, LAMINATED FIBER BOARD, WHICH COMPRISES SUBJECTING BLOCKS OF WOOD TO THE ACTION OF STEAM AND THEN GRINDING THE STEAMED BLOCKS, THEREBY PRODUCING A PARTIALLY HYDROLYZED GROUND WOOD CONTAINING LIGNIN AND WOOD ACIDS, PREPARING A BEATER FURNISH CONTAINING SAID STEAMED GROUND WOOD AND EXTRACTED PINE WOOD PITCH, BEATING SAID FURNISH INTO A HOMOGENEOUS MIXTURE, FORMING SAID MIXTURE INTO A WEB, PARTIALLY DRYING THE WEB, COATING AT LEAST ONE SIDE OF SAID PARTIALLY DRIED WEB WITH THERMOSETTING SYNTHETIC RESIN, SUPERIMPOSING SHEETS OF SAID COATED WEB TO FORM A LAMINATE HAVING AT LEAST ONE RESIN COATING BETWEEN EACH PAIR OF SHEETS AND A RESIN COATING ON EACH OUTER SURFACE OF THE LAMINATE, AND CONSOLIDATING SAID LAMINATE, CAUSING SAID RESIN TO FLOW, AND SETTING SAID THERMOSETTING RESIN, BY SUBJECTING THE LAMINATE TO HEAT AND PRESSURE.